[email protected] 1–408–923–6800

Total Page:16

File Type:pdf, Size:1020Kb

Xtls@Minresco.Com 1–408–923–6800 www.minresco.com [email protected] 1–408–923–6800 Systematic Mineral List ABERNATHYITE - Rivieral, Lodeve, Herault Dept., France ABHURITE - Wreck of SS Cheerful, 14 Miles NNW of St. Ives, Cornwall, England ACANTHITE – Alberoda, Erzgebirge, Saxony, Germany ACANTHITE – Brahmaputra Vein, Alberoda, Schlema-Hartenstein District, Erzgebirge, Saxony, Germany ACANTHITE – Centennial Eureka Mine, Tintic District, Juab County, Utah ACANTHITE – Horn Silver Mine, near Frisco, Beaver County, Utah ACANTHITE – Ingleterra Mine, Santa Eulalia, Chihuahua, Mexico ACANTHITE – Pribram-Trebsco, Central Bohemia, Czech Republic ACANTHITE – Tombstone, Cochise County, Arizona ACHTARAGDITE - Achtaragda River/Wilui River District, Sakha Republic (Yakutia), Russian Fed. ADAMITE Var. Cuproadamite – Kintore Opencut, Broken Hill, New South Wales, Australia ADAMITE Var. Cuproadamite - Mine de Cap-Garonne, near Hyers, Dept. Var, France ADAMITE Var. Cuproadamite - Tsumcorp Mine, Tsumeb, Namibia ADAMITE Var. Cuproadamite – Zinc Hill, Darwin, Inyo County, California ADAMITE Var. Manganoan Adamite – El Potosi Mine, Santa Eulalia, Chihuahua, Mexico ADREALITE – Moorba Cave, Jurien Bay, W.A., Australia AEGIRINE Var. Blanfordite - Tirodi Mines, Madhya Pradesh, Central Provinces, India T AENIGMATITE – Chibiny (Khibina) Massif, Kola Peninsula, Russia AERINITE - Estopinan, Pyrenees Mountains, Huesca Province, Spain AESCHYNITE-(Y) (Priorite) – Arendal, Aust-Adger, Norway AFGHANITE – Casa Collina, Pitigliano, Grosseto, Tuscany (Toscana), Italy AFGHANITE - Laacher See Region, Ettringen, Bellerberg, Eifel District, Rheinland-Pfalz, Germany AFGHANITE – Sar-e-Sang, Bedakhshan Province, Afghanistan AFWILLITE - Crestmore Quarry, near Riverside, Riverside County, California AGARDITE-(Ce) - Tin Stope, Majuba Hill, Pershing County, Nevada AGARDITE-(La) - Hilarion Mine, near Kamareza, Laurium, Attica Peninsula, Greece AGARDITE-(La) - Red Cloud Copper Mine, Gallinas Mountains, Lincoln County, New Mexico AGARDITE-(Y) - Bou-Skour Mine, Jebel Sarhro, Ouarzazate, Southern Morocco T AGARDITE-(Y) - Clara Mine, Black Forest (Schwarzwald), Baden, Germany AGARDITE-(Y) - Copper Stope, Majuba Hill Mine, Pershing County, Nevada AGRELLITE - Kipawa Complex, Villedieu Township, Temiscaming County, Quebec, Canada T AHLFELDITE – El Dragon Mine, Potosi, Bolivia AIKINITE – Amax Mine, Kitsault, near Alice Arm, B.C., Canada AIKINITE - Beresovsk District, near Ekaterinburg (Sverdlovsk), Ural Mountains, Russia T AIKINITE - Magruder Mountains, Esmeralda County, Nevada AJOITE – New Cornelia Mine, Ajo, Pima County, Arizona T AKATOREITE - near the mouth of Akatore Creek, Taieri, Eastern Otago Prov., New Zealand T AKTASHITE - Bambollita Mine, Moctezuma, Sonora, Mexico ALABANDITE - near the mouth of Akatore Creek, Taieri, Eastern Otago Province, New Zealand ALABANDITE - Preciosa Sangue de Cristo Mine, near Tlalchichuca, State of Puebla, Mexico ALABANDITE – Uchucchacua Mine, Oyon Province, Lima Department, Peru ALAMOSITE – Artillery Peak, Mohave County, Arizona ALBERTITE - Frederick Brook, 6.4 Km SW of Hillsborough, Albert County, N.B., Canada T ALBITE Var. Andesine – Portland Harbour Trust Quarry, Cape Sir William Grant, Portland, Victoria, Australia ALDERMANITE - "Klemm's" Moculta Phosphate Quarry, near Angaston, S.A., Australia T ALGODONITE - Mohawk #2 Mine, Keweenaw Peninsula, Michigan ALGODONITE - Sheldon-Columbia Mine, Portage Lake, Houghton County, Michigan ALLANITE - Ashe County, North Carolina ALLANITE-(Ce) - 20 Miles No. of Reno, Washoe County, Nevada ALLANITE-(Ce) - Bastnaes Mine, Riddarhyttan, Vastmanland, Sweden ALLANITE-(Ce) - Bucky Mine, Ohio City, Gunnison County, Colorado ALLANITE-(Ce) – Burroughs Pegmatite, Jefferson County, Colorado ALLANITE-(Ce) - Cuzzago, Ossola Valley, Italy ALLANITE-(Ce) – Gloserheia, Froland, near Arendal, Aust-Adger, Norway ALLANITE-(Ce) - McAlmond Creek, Potrero, San Diego County, California ALLANITE-(Ce) - Mina Tiro Estrella, El Capitan Mountains, Lincoln County, New Mexico ALLANITE-(Ce) – Sawatch Mountains, near Buena Vista, Chaffee County, Colorado ALLANITE-(Y) – Sawatch Mountains, near Buena Vista, Chaffee County, Colorado ALLEGHANYITE – Trotter Dump, Franklin Mine, Franklin, Sussex County, New Jersey ALLEMONTITE - Rio Moctezuma, Municipio de Moctezuma, Sonora, Mexico - See STIBARSEN ALLEMONTITE - Trebsco, Bohemia, Czechoslovakia - See STIBARSEN ALLOPHANE – Apex Mine, Washington County, Utah ALLOPHANE - El Dragon Mine, Potosi, Bolivia ALLOPHANE - Inspiration Mine, Globe-Miami District, Gila County, Arizona ALLOPHANE – Mammoth-St. Anthony Mine, Tiger, Pinal County, Arizona ALLOPHANE - Tynagh Mine, near Maam, County Galway, Southern Ireland ALSTONITE – Bromley Hills Mine, Nenthead, Cumbria, England ALSTONITE – Brownley Hill Mine, Nenthead, Cumbria, England ALSTONITE – Fallowfield Mine, Northumberland, England ALTAITE - Hilltop Mine, Organ Mountains, Dona Ana County, New Mexico ALTAITE - Koch-Bulak Gold Deposit, near Angren, Eastern Uzbekistan ALTHAUSITE - Overntjern, Modum, Buskerud, Norway ALTHAUSITE - Skutterud, Modum, Norway ALTHAUSITE - Tingelstadtjern, Modum, Norway T ALUMOHYDROCALCITE - Mt. Hamilton, Santa Clara County, California ALUNITE – El Dragon Mine, Potosi, Bolivia ALUNITE – Marysvale, Piute County, Utah ALUNITE – Wendy Pit, El Indio Gold Mine, Tambo, Coquimbo District, Chile ALUNITE - Willow Springs, near Mojave, Kern County, California ALURGITE - Praborna Mine, St. Marcel, Aosta, Italy - See MUSCOVITE Var. Alurgite AMBLYGONITE – Beecher Lode Claim, 4.9 Mi. SE of Custer, Custer Co., South Dakota AMEGHINITE – Tincalayu Borax Deposit, Salta, Argentina T AMEGHINITE – Tincalayu Borax Deposit, Salta, Argentina T AMESITE (Chromian) – Sarany Chromite Deposit, Bisersk, Ural Mountains, Russia AMOSITE (variety of GRUNERITE) - Penge Mine, Transvaal, Republic of South Africa – See GRUNERITE AMPANGABEITE – Ampangabe, Madagascar - See SAMARSKITE-(Y) ANANDITE - Esquire No. 7 Claim, Big Creek, Fresno County, California ANAPAITE - Kerch Peninsula, Crimea Oblast, Ukraine ANCYLITE-(Ce) – DeMix Quarry, Mont St. Hilaire, Quebec, Canada ANDERSONITE – Atomic King #2 Mine, Cane Wash, San Juan County, Utah ANDERSONITE – D-Day No. 2 Mine, Yellow Cat District, Grand County, Utah ANDERSONITE - Monte Cristo Mine, Cane Springs Canyon, near Moab, San Juan County, Utah ANDORITE – San Jose Mine, Dept. Oruro, Bolivia ANDRADITE Var. Polyadelphite (Manganiferous) – Sterling Mine, Sterling Hill, Ogdensburg, Sussex County, New Jersey ANHYDRITE – Campiano Mine, Boccheggiano, near Grosseto, Tuscany, Central Italy ANHYDRITE – Naica, Municipio de Saucillo, Chihuahua, Mexico ANNABERGITE - Candelaria Mine, Mineral County, Nevada ANNABERGITE - Kalkar Quarry, Santa Cruz County, California ANNABERGITE – Kamareza Mine, Laurium, Attica, Greece ANNABERGITE – Ramsbeck Mine, Dornberg, Sauerland, Germany ANNITE – Katugin River, Siberia, Russia ANNITE – Saga Quarry, Tvedalen, Norway ANNITE – Suishoyama Pegmatite, Fukushima Prefecture, Tohoku Region, Honshu Island, Japan ANORTHITE – Miyake Island, Tokyo Bay, Honshu, Japan ANORTHITE – Yoichi City, Yoichi-Gun, Hokkaido Pref., Japan ANTHOPHYLLITE - Carleton Talc Mine, near Chester, Windsor County, Vermont ANTHOPHYLLITE – Kopperberg, Sweden ANTHOPHYLLITE – Kragero, near Risor, Vestfold, Southern Norway ANTIMONPEARCEITE – Clara Mine, Oberwolfach, Baden, Germany ANTIMONY (native) - Alpha Shaft, Murchison Mine, Gravelotte, Transvaal, Republic of South Africa ANTIMONY (native) - Consolidated Durham Mines, Lake County, New Brunswick, Canada ANTIMONY (native) – Huasco, Atacama, Chile ANTIMONY (native) – Kalliolampi (Kalliosalo), Nurmo, Finland ANTIMONY (native) - Lac Nicolet Antimony Mine, Ham Sud Township, Quebec, Canada ANTIMONY (native) - near Kernville, Kern County, California ANTIMONY (native) - Seinajoki, Vassa, Central Finland ANTIMONY (native) - Tom Moore Mine, Erskine Creek Mining District, Kern County, California ANTLERITE – Chuquicamata, Antofagasta Province, Chile APACHITE - Christmas Mine, near Hayden, Gila County, Arizona T APATITE-(CaOH) - Oksoyekollen, Snarum, Modum, Buskerud, Norway APATITE-(CaOH) - David Mosiah Claim, Cerro Huanaquino, Potosi Department, Bolivia APATITE-(CaOH) – Mo-i-Rana, Rana, Nordland, Norway APHTHITALITE - Searles Lake, San Bernardino County, California APUANITE - Buca della Vena Mine, Apuan Alps, Lucca Province, Tuscany, Italy T a-QUARTZ psu. b-QUARTZ – Luzon Island, Philippines ARAGONITE Var. Tarnowitzite - Tsumeb, Namibia T ARDENNITE - Salm-Chateau, Ardennes, Belgium T ARGENTOJAROSITE – Santa Ana, State of Sonora, Mexico ARMENITE - 10 Miles N.E. of North Bend, King County, Washington ARMENITE - Simplon Pass, Wasenalp, Valais, Switzerland ARMSTRONGITE - Khan-Bogdinskii Massif, Central Gobi Desert, Mongolia T ARROJADITE – Nancy No. 2 Mine, Groton Area, New Hampshire ARROJADITE – Rapid Creek/Big Fish River Area, Yukon Territory, Canada ARSENIC (native) – Jachymov (Joachimstahl), Bohemia, Czech Republic ARSENIC (native) - Niederschlema, Saxony, Germany - See CHLOANTHITE ARSENIC (native) - Pöhla-Tellerhäuser Mine, Pöhla, Schwarzenberg District, Erzgebirge, Saxony, Germany ARSENIC (native) – Svornost Mine, Jachymov (Joachimstahl), Bohemia, Czech Republic ARSENIC (native) - Vancouver Island, British Columbia, Canada ARSENIOSIDERITE – Gold Hill, Tooele County, Utah ARSENIOSIDERITE – Mina Ojuela, Mapimi, Durango, Mexico ARSENIOSIDERITE – Prospect W. of Rhyolite Pass, N. of Luning, Mineral County, Nevada ARSENOCRANDALLITE - Dolores Mine, Pastrana, Murcia, Spain – See BARAHONAITE-(Fe) ARSENOLITE – Chichibu Mining District, Saitama
Recommended publications
  • An Application of Near-Infrared and Mid-Infrared Spectroscopy to the Study of 3 Selected Tellurite Minerals: Xocomecatlite, Tlapallite and Rodalquilarite 4 5 Ray L
    QUT Digital Repository: http://eprints.qut.edu.au/ Frost, Ray L. and Keeffe, Eloise C. and Reddy, B. Jagannadha (2009) An application of near-infrared and mid- infrared spectroscopy to the study of selected tellurite minerals: xocomecatlite, tlapallite and rodalquilarite. Transition Metal Chemistry, 34(1). pp. 23-32. © Copyright 2009 Springer 1 2 An application of near-infrared and mid-infrared spectroscopy to the study of 3 selected tellurite minerals: xocomecatlite, tlapallite and rodalquilarite 4 5 Ray L. Frost, • B. Jagannadha Reddy, Eloise C. Keeffe 6 7 Inorganic Materials Research Program, School of Physical and Chemical Sciences, 8 Queensland University of Technology, GPO Box 2434, Brisbane Queensland 4001, 9 Australia. 10 11 Abstract 12 Near-infrared and mid-infrared spectra of three tellurite minerals have been 13 investigated. The structure and spectral properties of two copper bearing 14 xocomecatlite and tlapallite are compared with an iron bearing rodalquilarite mineral. 15 Two prominent bands observed at 9855 and 9015 cm-1 are 16 2 2 2 2 2+ 17 assigned to B1g → B2g and B1g → A1g transitions of Cu ion in xocomecatlite. 18 19 The cause of spectral distortion is the result of many cations of Ca, Pb, Cu and Zn the 20 in tlapallite mineral structure. Rodalquilarite is characterised by ferric ion absorption 21 in the range 12300-8800 cm-1. 22 Three water vibrational overtones are observed in xocomecatlite at 7140, 7075 23 and 6935 cm-1 where as in tlapallite bands are shifted to low wavenumbers at 7135, 24 7080 and 6830 cm-1. The complexity of rodalquilarite spectrum increases with more 25 number of overlapping bands in the near-infrared.
    [Show full text]
  • Xrd and Tem Studies on Nanophase Manganese
    Clays and Clay Minerals, Vol. 64, No. 5, 488–501, 2016. 1 1 2 2 3 XRD AND TEM STUDIES ON NANOPHASE MANGANESE OXIDES IN 3 4 FRESHWATER FERROMANGANESE NODULES FROM GREEN BAY, 4 5 5 6 LAKE MICHIGAN 6 7 7 8 8 S EUNGYEOL L EE AND H UIFANG X U* 9 9 NASA Astrobiology Institute, Department of Geoscience, University of Wisconsin Madison, Madison, 10 À 10 1215 West Dayton Street, A352 Weeks Hall, Wisconsin 53706 11 11 12 12 13 Abstract—Freshwater ferromanganese nodules (FFN) from Green Bay, Lake Michigan have been 13 14 investigated by X-ray powder diffraction (XRD), micro X-ray fluorescence (XRF), scanning electron 14 microscopy (SEM), high-resolution transmission electron microscopy (HRTEM), and scanning 15 transmission electron microscopy (STEM). The samples can be divided into three types: Mn-rich 15 16 nodules, Fe-Mn nodules, and Fe-rich nodules. The manganese-bearing phases are todorokite, birnessite, 16 17 and buserite. The iron-bearing phases are feroxyhyte, goethite, 2-line ferrihydrite, and proto-goethite 17 18 (intermediate phase between feroxyhyte and goethite). The XRD patterns from a nodule cross section 18 19 suggest the transformation of birnessite to todorokite. The TEM-EDS spectra show that todorokite is 19 associated with Ba, Co, Ni, and Zn; birnessite is associated with Ca and Na; and buserite is associated with 20 2+ +2 3+ 20 Ca. The todorokite has an average chemical formula of Ba0.28(Zn0.14Co0.05 21 2+ 4+ 3+ 3+ 3+ 2+ 21 Ni0.02)(Mn4.99Mn0.82Fe0.12Co0.05Ni0.02)O12·nH2O.
    [Show full text]
  • Metamorphism of Sedimentary Manganese Deposits
    Acta Mineralogica-Petrographica, Szeged, XX/2, 325—336, 1972. METAMORPHISM OF SEDIMENTARY MANGANESE DEPOSITS SUPRIYA ROY ABSTRACT: Metamorphosed sedimentary deposits of manganese occur extensively in India, Brazil, U. S. A., Australia, New Zealand, U. S. S. R., West and South West Africa, Madagascar and Japan. Different mineral-assemblages have been recorded from these deposits which may be classi- fied into oxide, carbonate, silicate and silicate-carbonate formations. The oxide formations are represented by lower oxides (braunite, bixbyite, hollandite, hausmannite, jacobsite, vredenburgite •etc.), the carbonate formations by rhodochrosite, kutnahorite, manganoan calcite etc., the silicate formations by spessartite, rhodonite, manganiferous amphiboles and pyroxenes, manganophyllite, piedmontite etc. and the silicate-carbonate formations by rhodochrosite, rhodonite, tephroite, spessartite etc. Pétrographie and phase-equilibia data indicate that the original bulk composition in the sediments, the reactions during metamorphism (contact and regional and the variations and effect of 02, C02, etc. with rise of temperature, control the mineralogy of the metamorphosed manga- nese formations. The general trend of formation and transformation of mineral phases in oxide, carbonate, silicate and silicate-carbonate formations during regional and contact metamorphism has, thus, been established. Sedimentary manganese formations, later modified by regional or contact metamorphism, have been reported from different parts of the world. The most important among such deposits occur in India, Brazil, U.S.A., U.S.S.R., Ghana, South and South West Africa, Madagascar, Australia, New Zealand, Great Britain, Japan etc. An attempt will be made to summarize the pertinent data on these metamorphosed sedimentary formations so as to establish the role of original bulk composition of the sediments, transformation and reaction of phases at ele- vated temperature and varying oxygen and carbon dioxide fugacities in determin- ing the mineral assemblages in these deposits.
    [Show full text]
  • Mineral Processing
    Mineral Processing Foundations of theory and practice of minerallurgy 1st English edition JAN DRZYMALA, C. Eng., Ph.D., D.Sc. Member of the Polish Mineral Processing Society Wroclaw University of Technology 2007 Translation: J. Drzymala, A. Swatek Reviewer: A. Luszczkiewicz Published as supplied by the author ©Copyright by Jan Drzymala, Wroclaw 2007 Computer typesetting: Danuta Szyszka Cover design: Danuta Szyszka Cover photo: Sebastian Bożek Oficyna Wydawnicza Politechniki Wrocławskiej Wybrzeze Wyspianskiego 27 50-370 Wroclaw Any part of this publication can be used in any form by any means provided that the usage is acknowledged by the citation: Drzymala, J., Mineral Processing, Foundations of theory and practice of minerallurgy, Oficyna Wydawnicza PWr., 2007, www.ig.pwr.wroc.pl/minproc ISBN 978-83-7493-362-9 Contents Introduction ....................................................................................................................9 Part I Introduction to mineral processing .....................................................................13 1. From the Big Bang to mineral processing................................................................14 1.1. The formation of matter ...................................................................................14 1.2. Elementary particles.........................................................................................16 1.3. Molecules .........................................................................................................18 1.4. Solids................................................................................................................19
    [Show full text]
  • Explore the Northern Cape Province
    Cultural Guiding - Explore The Northern Cape Province When Schalk van Niekerk traded all his possessions for an 83.5 carat stone owned by the Griqua Shepard, Zwartboy, Sir Richard Southey, Colonial Secretary of the Cape, declared with some justification: “This is the rock on which the future of South Africa will be built.” For us, The Star of South Africa, as the gem became known, shines not in the East, but in the Northern Cape. (Tourism Blueprint, 2006) 2 – WildlifeCampus Cultural Guiding Course – Northern Cape Module # 1 - Province Overview Component # 1 - Northern Cape Province Overview Module # 2 - Cultural Overview Component # 1 - Northern Cape Cultural Overview Module # 3 - Historical Overview Component # 1 - Northern Cape Historical Overview Module # 4 - Wildlife and Nature Conservation Overview Component # 1 - Northern Cape Wildlife and Nature Conservation Overview Module # 5 - Namaqualand Component # 1 - Namaqualand Component # 2 - The Hantam Karoo Component # 3 - Towns along the N14 Component # 4 - Richtersveld Component # 5 - The West Coast Module # 5 - Karoo Region Component # 1 - Introduction to the Karoo and N12 towns Component # 2 - Towns along the N1, N9 and N10 Component # 3 - Other Karoo towns Module # 6 - Diamond Region Component # 1 - Kimberley Component # 2 - Battlefields and towns along the N12 Module # 7 - The Green Kalahari Component # 1 – The Green Kalahari Module # 8 - The Kalahari Component # 1 - Kuruman and towns along the N14 South and R31 Northern Cape Province Overview This course material is the copyrighted intellectual property of WildlifeCampus. It may not be copied, distributed or reproduced in any format whatsoever without the express written permission of WildlifeCampus. 3 – WildlifeCampus Cultural Guiding Course – Northern Cape Module 1 - Component 1 Northern Cape Province Overview Introduction Diamonds certainly put the Northern Cape on the map, but it has far more to offer than these shiny stones.
    [Show full text]
  • Materializing Rival Ground States in the Barlowite Family of Kagome Magnets: Quantum Spin Liquid, Spin Ordered, and Valence Bond Crystal States ✉ Rebecca W
    www.nature.com/npjquantmats ARTICLE OPEN Materializing rival ground states in the barlowite family of kagome magnets: quantum spin liquid, spin ordered, and valence bond crystal states ✉ Rebecca W. Smaha 1,2,12 , Wei He 1,3,12, Jack Mingde Jiang 1,4, Jiajia Wen 1, Yi-Fan Jiang 1, John P. Sheckelton 1, Charles J. Titus 5, Suyin Grass Wang 6, Yu-Sheng Chen 6, Simon J. Teat 7, Adam A. Aczel 8,9, Yang Zhao 10,11, Guangyong Xu10, ✉ Jeffrey W. Lynn 10, Hong-Chen Jiang 1 and Young S. Lee 1,4 1 fi The spin-2 kagome antiferromagnet is considered an ideal host for a quantum spin liquid (QSL) ground state. We nd that when the bonds of the kagome lattice are modulated with a periodic pattern, new quantum ground states emerge. Newly synthesized crystalline barlowite (Cu4(OH)6FBr) and Zn-substituted barlowite demonstrate the delicate interplay between singlet states and spin 1 order on the spin-2 kagome lattice. Comprehensive structural measurements demonstrate that our new variant of barlowite maintains hexagonal symmetry at low temperatures with an arrangement of distorted and undistorted kagome triangles, for which numerical simulations predict a pinwheel valence bond crystal (VBC) state instead of a QSL. The presence of interlayer spins eventually leads to an interesting pinwheel q = 0 magnetic order. Partially Zn-substituted barlowite (Cu3.44Zn0.56(OH)6FBr) has an ideal kagome lattice and shows QSL behavior, indicating a surprising robustness of the QSL against interlayer impurities. The magnetic susceptibility is similar to that of herbertsmithite, even though the Cu2+ impurities are above the percolation threshold 1234567890():,; for the interlayer lattice and they couple more strongly to the nearest kagome moment.
    [Show full text]
  • Uraninite Alteration in an Oxidizing Environment and Its Relevance to the Disposal of Spent Nuclear Fuel
    TECHNICAL REPORT 91-15 Uraninite alteration in an oxidizing environment and its relevance to the disposal of spent nuclear fuel Robert Finch, Rodney Ewing Department of Geology, University of New Mexico December 1990 SVENSK KÄRNBRÄNSLEHANTERING AB SWEDISH NUCLEAR FUEL AND WASTE MANAGEMENT CO BOX 5864 S-102 48 STOCKHOLM TEL 08-665 28 00 TELEX 13108 SKB S TELEFAX 08-661 57 19 original contains color illustrations URANINITE ALTERATION IN AN OXIDIZING ENVIRONMENT AND ITS RELEVANCE TO THE DISPOSAL OF SPENT NUCLEAR FUEL Robert Finch, Rodney Ewing Department of Geology, University of New Mexico December 1990 This report concerns a study which was conducted for SKB. The conclusions and viewpoints presented in the report are those of the author (s) and do not necessarily coincide with those of the client. Information on SKB technical reports from 1977-1978 (TR 121), 1979 (TR 79-28), 1980 (TR 80-26), 1981 (TR 81-17), 1982 (TR 82-28), 1983 (TR 83-77), 1984 (TR 85-01), 1985 (TR 85-20), 1986 (TR 86-31), 1987 (TR 87-33), 1988 (TR 88-32) and 1989 (TR 89-40) is available through SKB. URANINITE ALTERATION IN AN OXIDIZING ENVIRONMENT AND ITS RELEVANCE TO THE DISPOSAL OF SPENT NUCLEAR FUEL Robert Finch Rodney Ewing Department of Geology University of New Mexico Submitted to Svensk Kämbränslehantering AB (SKB) December 21,1990 ABSTRACT Uraninite is a natural analogue for spent nuclear fuel because of similarities in structure (both are fluorite structure types) and chemistry (both are nominally UOJ. Effective assessment of the long-term behavior of spent fuel in a geologic repository requires a knowledge of the corrosion products produced in that environment.
    [Show full text]
  • Inis: Terminology Charts
    IAEA-INIS-13A(Rev.0) XA0400071 INIS: TERMINOLOGY CHARTS agree INTERNATIONAL ATOMIC ENERGY AGENCY, VIENNA, AUGUST 1970 INISs TERMINOLOGY CHARTS TABLE OF CONTENTS FOREWORD ... ......... *.* 1 PREFACE 2 INTRODUCTION ... .... *a ... oo 3 LIST OF SUBJECT FIELDS REPRESENTED BY THE CHARTS ........ 5 GENERAL DESCRIPTOR INDEX ................ 9*999.9o.ooo .... 7 FOREWORD This document is one in a series of publications known as the INIS Reference Series. It is to be used in conjunction with the indexing manual 1) and the thesaurus 2) for the preparation of INIS input by national and regional centrea. The thesaurus and terminology charts in their first edition (Rev.0) were produced as the result of an agreement between the International Atomic Energy Agency (IAEA) and the European Atomic Energy Community (Euratom). Except for minor changesq the terminology and the interrela- tionships btween rms are those of the December 1969 edition of the Euratom Thesaurus 3) In all matters of subject indexing and ontrol, the IAEA followed the recommendations of Euratom for these charts. Credit and responsibility for the present version of these charts must go to Euratom. Suggestions for improvement from all interested parties. particularly those that are contributing to or utilizing the INIS magnetic-tape services are welcomed. These should be addressed to: The Thesaurus Speoialist/INIS Section Division of Scientific and Tohnioal Information International Atomic Energy Agency P.O. Box 590 A-1011 Vienna, Austria International Atomic Energy Agency Division of Sientific and Technical Information INIS Section June 1970 1) IAEA-INIS-12 (INIS: Manual for Indexing) 2) IAEA-INIS-13 (INIS: Thesaurus) 3) EURATOM Thesaurusq, Euratom Nuclear Documentation System.
    [Show full text]
  • Thirty-Fourth List of New Mineral Names
    MINERALOGICAL MAGAZINE, DECEMBER 1986, VOL. 50, PP. 741-61 Thirty-fourth list of new mineral names E. E. FEJER Department of Mineralogy, British Museum (Natural History), Cromwell Road, London SW7 5BD THE present list contains 181 entries. Of these 148 are Alacranite. V. I. Popova, V. A. Popov, A. Clark, valid species, most of which have been approved by the V. O. Polyakov, and S. E. Borisovskii, 1986. Zap. IMA Commission on New Minerals and Mineral Names, 115, 360. First found at Alacran, Pampa Larga, 17 are misspellings or erroneous transliterations, 9 are Chile by A. H. Clark in 1970 (rejected by IMA names published without IMA approval, 4 are variety because of insufficient data), then in 1980 at the names, 2 are spelling corrections, and one is a name applied to gem material. As in previous lists, contractions caldera of Uzon volcano, Kamchatka, USSR, as are used for the names of frequently cited journals and yellowish orange equant crystals up to 0.5 ram, other publications are abbreviated in italic. sometimes flattened on {100} with {100}, {111}, {ill}, and {110} faces, adamantine to greasy Abhurite. J. J. Matzko, H. T. Evans Jr., M. E. Mrose, lustre, poor {100} cleavage, brittle, H 1 Mono- and P. Aruscavage, 1985. C.M. 23, 233. At a clinic, P2/c, a 9.89(2), b 9.73(2), c 9.13(1) A, depth c.35 m, in an arm of the Red Sea, known as fl 101.84(5) ~ Z = 2; Dobs. 3.43(5), D~alr 3.43; Sharm Abhur, c.30 km north of Jiddah, Saudi reflectances and microhardness given.
    [Show full text]
  • Optical Properties of Common Rock-Forming Minerals
    AppendixA __________ Optical Properties of Common Rock-Forming Minerals 325 Optical Properties of Common Rock-Forming Minerals J. B. Lyons, S. A. Morse, and R. E. Stoiber Distinguishing Characteristics Chemical XI. System and Indices Birefringence "Characteristically parallel, but Mineral Composition Best Cleavage Sign,2V and Relief and Color see Fig. 13-3. A. High Positive Relief Zircon ZrSiO. Tet. (+) 111=1.940 High biref. Small euhedral grains show (.055) parallel" extinction; may cause pleochroic haloes if enclosed in other minerals Sphene CaTiSiOs Mon. (110) (+) 30-50 13=1.895 High biref. Wedge-shaped grains; may (Titanite) to 1.935 (0.108-.135) show (110) cleavage or (100) Often or (221) parting; ZI\c=51 0; brownish in very high relief; r>v extreme. color CtJI\) 0) Gamet AsB2(SiO.la where Iso. High Grandite often Very pale pink commonest A = R2+ and B = RS + 1.7-1.9 weakly color; inclusions common. birefracting. Indices vary widely with composition. Crystals often euhedraL Uvarovite green, very rare. Staurolite H2FeAI.Si2O'2 Orth. (010) (+) 2V = 87 13=1.750 Low biref. Pleochroic colorless to golden (approximately) (.012) yellow; one good cleavage; twins cruciform or oblique; metamorphic. Olivine Series Mg2SiO. Orth. (+) 2V=85 13=1.651 High biref. Colorless (Fo) to yellow or pale to to (.035) brown (Fa); high relief. Fe2SiO. Orth. (-) 2V=47 13=1.865 High biref. Shagreen (mottled) surface; (.051) often cracked and altered to %II - serpentine. Poor (010) and (100) cleavages. Extinction par- ~ ~ alleL" l~4~ Tourmaline Na(Mg,Fe,Mn,Li,Alk Hex. (-) 111=1.636 Mod. biref.
    [Show full text]
  • New Mineral Names*
    American Mineralogist, Volume 97, pages 2064–2072, 2012 New Mineral Names* G. DIEGO GATTA,1 FERNANDO CÁMARA,2 KIMBERLY T. TAIT,3,† AND DMITRY BELAKOVSKIY4 1Dipartimento Scienze della Terra, Università degli Studi di Milano, Via Botticelli, 23-20133 Milano, Italy 2Dipartimento di Scienze della Terra, Università di degli Studi di Torino, Via Valperga Caluso, 35-10125 Torino, Italy 3Department of Natual History, Royal Ontario Museum, 100 Queens Park, Toronto, Ontario M5S 2C6, Canada 4Fersman Mineralogical Museum, Russian Academy of Sciences, Moscow, Russia IN THIS ISSUE This New Mineral Names has entries for 12 new minerals, including: agardite-(Nd), ammineite, byzantievite, chibaite, ferroericssonite, fluor-dravite, fluorocronite, litochlebite, magnesioneptunite, manitobaite, orlovite, and tashelgite. These new minerals come from several different journals: Canadian Mineralogist, European Journal of Mineralogy, Journal of Geosciences, Mineralogical Magazine, Nature Communications, Novye dannye o mineralakh (New data on minerals), and Zap. Ross. Mineral. Obshch. We also include seven entries of new data. AGARDITE-(ND)* clusters up to 2 mm across. Agardite-(Nd) is transparent, light I.V. Pekov, N.V. Chukanov, A.E. Zadov, P. Voudouris, A. bluish green (turquoise-colored) in aggregates to almost color- Magganas, and A. Katerinopoulos (2011) Agardite-(Nd), less in separate thin needles or fibers. Streak is white. Luster is vitreous in relatively thick crystals and silky in aggregates. Mohs NdCu6(AsO4)3(OH)6·3H2O, from the Hilarion Mine, Lavrion, Greece: mineral description and chemical relations with other hardness is <3. Crystals are brittle, cleavage nor parting were members of the agardite–zálesíite solid-solution system. observed, fracture is uneven. Density could not be measured Journal of Geosciences, 57, 249–255.
    [Show full text]
  • General Index
    CAL – CAL GENERAL INDEX CACOXENITE United States Prospect quarry (rhombs to 3 cm) 25:189– Not verified from pegmatites; most id as strunzite Arizona 190p 4:119, 4:121 Campbell shaft, Bisbee 24:428n Unanderra quarry 19:393c Australia California Willy Wally Gully (spherulitic) 19:401 Queensland Golden Rule mine, Tuolumne County 18:63 Queensland Mt. Isa mine 19:479 Stanislaus mine, Calaveras County 13:396h Mt. Isa mine (some scepter) 19:479 South Australia Colorado South Australia Moonta mines 19:(412) Cresson mine, Teller County (1 cm crystals; Beltana mine: smithsonite after 22:454p; Brazil some poss. melonite after) 16:234–236d,c white rhombs to 1 cm 22:452 Minas Gerais Cripple Creek, Teller County 13:395–396p,d, Wallaroo mines 19:413 Conselheiro Pena (id as acicular beraunite) 13:399 Tasmania 24:385n San Juan Mountains 10:358n Renison mine 19:384 Ireland Oregon Victoria Ft. Lismeenagh, Shenagolden, County Limer- Last Chance mine, Baker County 13:398n Flinders area 19:456 ick 20:396 Wisconsin Hunter River valley, north of Sydney (“glen- Spain Rib Mountain, Marathon County (5 mm laths donite,” poss. after ikaite) 19:368p,h Horcajo mines, Ciudad Real (rosettes; crystals in quartz) 12:95 Jindevick quarry, Warregul (oriented on cal- to 1 cm) 25:22p, 25:25 CALCIO-ANCYLITE-(Ce), -(Nd) cite) 19:199, 19:200p Kennon Head, Phillip Island 19:456 Sweden Canada Phelans Bluff, Phillip Island 19:456 Leveäniemi iron mine, Norrbotten 20:345p, Québec 20:346, 22:(48) Phillip Island 19:456 Mt. St-Hilaire (calcio-ancylite-(Ce)) 21:295– Austria United States
    [Show full text]